International Journal for Multiscale Computational Engineering

Aims & Scope

The aim of the journal is to advance the research and practice in diverse areas of Multiscale Computational Science and Engineering.

The journal will publish original papers and educational articles of general value to the field that will bridge the gap between modeling, simulation and design of products based on multiscale principles.

The scope of the journal includes papers concerned with bridging of physical scales, ranging from the atomic level to full scale products and problems involving multiple physical processes interacting at multiple spatial and temporal scales.

The emerging areas of computational nanotechnology and computational biotechnology and computational energy sciences are of particular interest to the journal.

The journal is intended to be of interest and use to researchers and practitioners in academic, governmental and industrial communities.

View Aims & Scope

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Metrics & Ranking

Impact Factor

Year	Value
2025	1.4

SJR (SCImago Journal Rank)

Year	Value
2024	0.361

Quartile

Year	Value
2024	Q2

h-index

Year	Value
2024	35

Journal Rank

Year	Value
2024	14843

Journal Citation Indicator

Year	Value
2024	146

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Abstracting & Indexing

Journal is indexed in leading academic databases, ensuring global visibility and accessibility of our peer-reviewed research.

• Scopus
• Google Scholar
• Web of Science

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Subjects & Keywords

Journal’s research areas, covering key disciplines and specialized sub-topics in Computer Science and Engineering, designed to support cutting-edge academic discovery.

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Most Cited Articles

The Most Cited Articles section features the journal's most impactful research, based on citation counts. These articles have been referenced frequently by other researchers, indicating their significant contribution to their respective fields.

• AN ENERGY BASED FAILURE CRITERION FOR USE WITH PERIDYNAMIC STATES

  Citation: 266

  Authors: John, Stewart A., Weinong

• Toward Multiscale Modeling of Carbon Nanotube Transistors

  Citation: 222

  Authors: Jing, Supriyo, Mark, M. P.

• Coupling Methods for Continuum Model with Molecular Model

  Citation: 203

  Authors: Ted, S. P.

• ADAPTIVE REFINEMENT AND MULTISCALE MODELING IN 2D PERIDYNAMICS

  Citation: 198

  Authors: Florin, Youn Doh

• A Nonclassical Reddy-Levinson Beam Model Based on a Modified Couple Stress Theory

  Citation: 154

  Authors: H. M., Xin-Lin, J.N.

• ON THE ROLE OF THE INFLUENCE FUNCTION IN THE PERIDYNAMIC THEORY

  Citation: 146

  Authors: Pablo, Michael

• MODELING DYNAMIC FRACTURE AND DAMAGE IN A FIBER-REINFORCED COMPOSITE LAMINA WITH PERIDYNAMICS

  Citation: 101

  Authors: Wenke, Youn Doh, Florin

• COMPUTATIONAL HOMOGENIZATION METHOD AND REDUCED DATABASE MODEL FOR HYPERELASTIC HETEROGENEOUS STRUCTURES

  Citation: 94

  Authors: Julien, Eric, Qi-Chang

• ENERGY-PRESERVING MUSCLE TISSUE MODEL: FORMULATION AND COMPATIBLE DISCRETIZATIONS

  Citation: 90

  Authors: Dominique, P., P., M.

• Computational Evaluation of Strain Gradient Elasticity Constants

  Citation: 87

  Authors: R. H. J., N. A.

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